Acute Plasma Biomarkers of T Cell Activation Set-PointLevels and of Disease Progression in HIV-1 InfectionAnne-Sophie Liovat1,2, Marie-Anne Rey-Cuille3, Camille Lecuroux4, Beatrice Jacquelin1, Isabelle Girault4,
Gael Petitjean1, Yasmine Zitoun5,6, Alain Venet4, Francoise Barre-Sinoussi1, Pierre Lebon7,
Laurence Meyer5,6, Martine Sinet4, Michaela Muller-Trutwin1*
1 Institut Pasteur, Unite de Regulation des Infections Retrovirales, Paris, France, 2 Universite Paris Diderot, Paris, France, 3 Institut Pasteur, Unite de Recherche et
d’Expertise Epidemiologie des Maladies Emergentes, Paris, France, 4 Institut National de la Sante et de la Recherche Medicale (INSERM) U1012, Regulation de la reponse
immune: infection VIH-1 et auto-immunite, Universite Paris-Sud, Le Kremlin Bicetre, France, 5 INSERM U1018, Service d’Epidemiologie et de Sante Publique, AP-HP,
Universite Paris-Sud, Le Kremlin-Bicetre, France, 6 AP-HP, Laboratoire de Virologie, CHU Necker-Enfants Malades, Paris, France, 7 Hopital Cochin-Saint-Vincent de Paul &
Universite Paris Descartes, Laboratoire de Virologie, Paris, France
Abstract
T cell activation levels, viral load and CD4+ T cell counts at early stages of HIV-1 infection are predictive of the rate ofprogression towards AIDS. We evaluated whether the inflammatory profile during primary HIV-1 infection is predictive ofthe virological and immunological set-points and of disease progression. We quantified 28 plasma proteins during acuteand post-acute HIV-1 infection in individuals with known disease progression profiles. Forty-six untreated patients, enrolledduring primary HIV-1 infection, were categorized into rapid progressors, progressors and slow progressors according totheir spontaneous progression profile over 42 months of follow-up. Already during primary infection, rapid progressorsshowed a higher number of increased plasma proteins than progressors or slow progressors. The plasma levels of TGF-b1and IL-18 in primary HIV-1 infection were both positively associated with T cell activation level at set-point (6 months afteracute infection) and together able to predict 74% of the T cell activation variation at set-point. Plasma IP-10 was positivelyand negatively associated with, respectively, T cell activation and CD4+ T cell counts at set-point and capable to predict 30%of the CD4+ T cell count variation at set-point. Moreover, plasma IP-10 levels during primary infection were predictive ofrapid progression. In primary infection, IP-10 was an even better predictor of rapid disease progression than viremia or CD4+
T cell levels at this time point. The superior predictive capacity of IP-10 was confirmed in an independent group of 88 HIV-1infected individuals. Altogether, this study shows that the inflammatory profile in primary HIV-1 infection is associated withT cell activation levels and CD4+ T cell counts at set-point. Plasma IP-10 levels were of strong predictive value for rapiddisease progression. The data suggest IP-10 being an earlier marker of disease progression than CD4+ T cell counts orviremia levels.
Citation: Liovat A-S, Rey-Cuille M-A, Lecuroux C, Jacquelin B, Girault I, et al. (2012) Acute Plasma Biomarkers of T Cell Activation Set-Point Levels and of DiseaseProgression in HIV-1 Infection. PLoS ONE 7(10): e46143. doi:10.1371/journal.pone.0046143
Editor: Clive M. Gray, University of Cape Town, South Africa
Received July 24, 2012; Accepted August 28, 2012; Published October 2, 2012
Copyright: � 2012 Liovat et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permitsunrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by grants from the French National Agency for AIDS Research (ANRS), Institut Pasteur and the AREVA Foundation. G.P. andC.L. received a fellowship from ANRS. A-S.L. received fellowhips from the ‘‘Ministere de l’Enseignement Superieur et de la Recherche’’, ‘‘Universite Paris VII-DenisDiderot’’ and from Sidaction. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing Interests: The authors have declared that no competing interests exist.
* E-mail: [email protected]
Introduction
Several months after HIV-1 infection, blood CD4+ T cell
counts, plasma RNA viral load (VL) and CD8+ T cell activation
levels reach the so-called set-point. At this set-point, which is
generally reached after six months post-infection, the levels of the
virological and immunological markers, in particular T cell
activation levels, are predictive of the rapidity of disease
progression [1,2,3,4,5]. Initiation of antiretroviral treatment is
recommended based on CD4+ T cell numbers in blood. However,
during primary HIV infection (PHI), CD4+ T cells decline in
blood and VL is generally high. It is therefore difficult to
distinguish at this early stage of infection if the low CD4+ T cell
counts, or the high VL levels, are due to a particularly early
diagnosis (close to the VL peak) or rather should be considered as a
sign of bad prognosis. New early markers for disease progression
could help to determine if an early initiation of treatment is
desirable in those patients who are diagnosed during PHI.
Moreover, further insight into the early events during HIV-1
infection can help to better understand the mechanisms leading to
systemic T cell activation and progressive loss of blood CD4+ T
cells.
HIV-1 infection is characterized by a cytokine storm in the
plasma in the first weeks following infection [6]. The study of the
events occurring before and around the VL peak is possible in
humans, but only occasionally [6,7,8]. As an alternative, the study
of SIV infections in non-human primates has allowed the field to
gain crucial knowledge of the events occurring early in infection.
Pathogenic SIVmac infection in macaques is characterized by a
cytokine storm similar to the one described in HIV-1 infection [9].
In contrast, during non-pathogenic infection in natural hosts of
SIV, not as many cytokines are induced, and for those that are
induced, this induction is transient [10,11,12,13,14]. Such a
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transiently increased cytokine is IFN-a [12,15,16,17]. Concomi-
tantly with IFN-a, both macaques and natural hosts show a strong
induction of IFN-stimulated genes (ISG) like IP-10 (CXCL10)
during primary infection [15,18,19]. Again, these ISG inductions
are persistent in macaques, as in HIV-infected humans, but only
transient in natural hosts. Indeed, in the latter their expressions are
rapidly down-regulated [15,16,17,19]. By four weeks post-infec-
tion, only macaques, but not natural hosts, display significantly
increased plasma cytokines and ISG expressions.
It has been proposed that a particularly early induction of anti-
inflammatory proteins could help to down-regulate inflammation,
while their chronic production most likely contributes to
immunodeficiency [20]. In line with this, in natural hosts, anti-
inflammatory factors (IL-10, TGF-b1, PD-1), when induced, are
detected very early but do not persist [10,11,15,21].
The data on the differences in primary infection between
pathogenic and non-pathogenic SIV infection has led us to raise
the hypothesis that a strong inflammation, an uncontrolled IFN
response and/or a lack of early anti-inflammatory factors, could be
of bad prognosis for disease progression. Previous studies in
humans have largely analyzed the association between inflamma-
tion and disease progression in the chronic phase of HIV infection.
More recently, inflammatory profiles have also been studied more
extensively in primary HIV-1 infection [6,7,22,23]. However, only
two studies addressed the role of acute inflammation on disease
progression markers [24,25]. None of the studies included a long
term follow up of the patients and no data are available on the
predictive value of inflammation in PHI for T cell activation levels.
Here, we aimed to analyze whether a specific pro- or anti-
inflammatory profile during PHI is predictive of T cell activation
and disease progression in patients followed for several years
without treatment, in a well-characterized cohort of patients
enrolled in PHI [4,26]. The early levels of 28 plasma proteins,
including IFN-I inducible proteins and anti-inflammatory cyto-
kines, were quantified in patients for which disease progression
profiles were known. We analyzed whether there was a correlation
between these pro- and anti-inflammatory proteins in PHI and
disease progression markers, including T cell activation, at set-
point. We also evaluated whether the concentrations of these
proteins could predict the disease progression profile. Altogether,
our study reveals for the first time an association between
inflammation in PHI and T cell activation at set-point. Further-
more, IP-10 was an independent predictor of rapid disease
progression and our data suggest that, during PHI, IP-109s
capacity of prediction is stronger than that of VL and CD4+ T cell
counts.
Results
HIV-1 Infected Individuals Enrolled in PHI and theirDisease Progression Characteristics
In order to search whether there is an association between early
inflammatory profiles and disease progression, we quantified a
wide range of proteins (N = 28) in the plasma of a cohort of 46
patients (Table S1). The patients studied were part of the large,
very well characterized ANRS PRIMO cohort [4,26,27]. In this
cohort, all subjects were enrolled at the stage of PHI. PHI and
time post-infection was defined as previously described [4] and as
explained in the Material and Methods section below. The
majority of the patients were enrolled at Fiebig stage III-IV, which
is the most common situation in clinics regarding PHI. We
retrospectively selected among antiretroviral treatment-naive
patients those who displayed clearly distinct disease progression
profiles based on their CD4+ T cell counts and/or viremia levels
(Figure 1, Table S1). The patients were categorized into three
groups: 16 rapid progressors (RP), 19 progressors (P) and 11 slow
progressors (SP). The groups were defined based on their CD4+ T
cell decline over the years during the follow up (42 months post-
PHI), as described in the Material section. The three patient
groups were similar regarding age, gender distribution and
estimated time since infection, while CD4+ T cell counts were
different at M0 and at set-point (M6) between all groups, and
viremia levels differed significantly between RP and SP at all time
points (Table S1, Table S2).
Plasma samples were studied at three time points: during PHI
(M0) and 1 month later (M1), in order to consider two early time
points, as well as six months later (M6), in order to dispose of data
at a time, which is generally considered to correspond to the set-
point. Plasma samples were available for all 46 patients at M0 and
M1, and for 40 out of the 46 patients at M6 (12 RP, 18 P and
10 SP). All plasma samples analyzed were from antiretroviral
treatment-naive patients.
Eight Plasma Proteins were Increased during Primary HIV-1 Infection
We quantified the concentrations of each of the 28 proteins in
the 46 HIV-1 infected individuals and evaluated whether their
levels were different or not as compared to the respective protein
levels in healthy donors. The proteins examined were chosen
based on following criteria: they are either known to have a pro- or
anti-inflammatory role, to be inducible by IFN, to be increased
during PHI or to be associated with disease progression during
chronic HIV-1 and SIVmac primary infections [6,9,10,11,15]. At
M0, 8 soluble factors were significantly more elevated than in non-
infected individuals: IL-18, TNF-a, sIL2Ra, sTRAIL, IL-8, IP-10,
IL-10 and TGF-b1 (FDR, p,0.008) (Figure 2A). All proteins that
were increased at M0 were also increased at M1 and M6 with
respect to healthy donors, with the exceptions of TGF-b1 at M1
and TNF-a at M6 (Figure 2B). No other plasma proteins were
increased at M1 and M6 besides those already increased at M0.
All plasma samples were negative for IFN-a except for one rapid
progressor at M6 (data not shown).
Altogether, 6 pro- and 2 anti-inflammatory soluble factors out of
the 28 tested were increased during PHI.
Rapid Progressors Presented the Highest Number ofElevated Pro- and Anti-inflammatory Proteins duringPrimary HIV-1 Infection
We then investigated whether there were differences in the
protein concentrations according to the disease progression profile.
We compared the concentrations of the 28 soluble factors in each
group of patients, i.e. rapid progressors (RP), progressors (P) and
slow progressors (SP) to those in healthy donors. Interesting
differences according to the disease progression profile of the
patients were observed. Thus, in RP, 8 proteins were significantly
elevated at M0 (Figure 3A and Table S3). These analytes were the
same proteins that were increased when all patients were grouped
together (Figure 2), except for TGF-b1, which was not elevated in
any of the patient groups when comparing them to healthy donors
separately. In contrast to RP, P and SP displayed elevations for
only 4 and 3 proteins, respectively (Figure 3B + C and Table S3)
(FDR, p,0.005). At M1 and M6, there were again more soluble
factors elevated in RP (N = 4) than in P (N = 2 at M1 and M6) and
SP (N = 1 at M1 and N = 3 at M6) (FDR, p,0.002) (Table S3 &
Figure S1). Cytokines which were increased in RP or P, but not in
SP were: TNF-a, IL-1b, IL-8, IP-10 and IL-10.
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In conclusion, starting from M0, RP had a higher number of
elevated soluble factors than the other two patient groups (P and
SP).
Plasma IP-10 Concentrations in Primary Infection wereDifferent between Groups of Patients Progressing atDistinct Rates
We then addressed the question of whether the concentrations
of these proteins differed between the patient groups. We first
analyzed the differences in protein concentrations by comparing
all three groups concurrently. The analysis was performed using
the Cuzick’s test, which allows multiple, ordered group compar-
isons. Two out of the 28 proteins showed increases over the groups
(from the lowest levels in the SP, followed by the P and highest in
the RP) at all time points (M0, M1, M6). These were IP-10
(p,0.007) and IL-10 (p,0.001) (Figure 3D for M0, and data not
shown for M1 and M6).
We further explored the differences by comparing the groups
two-by-two. Only for IP-10 there was a significant difference in the
cytokine concentration between two groups of patients (Figure 3D).
The concentrations of IP-10 were indeed different between RP
and P, and also between RP and SP (p,0.005). These differences
were observed at all time points (M0, M1, M6) (Figure 3D for M0,
and data not shown for M1 and M6).
IP-10, TGF-b1 and IL-18 in PHI were Associated with T CellActivation at Set-point
To analyze if the cytokine levels in PHI were associated with
markers of disease progression, we evaluated whether the
concentrations of one or more of the 28 proteins at M0 correlate
with viremia, CD4+ T cell counts and/or T cell activation levels at
set-point (M6). Three cytokines (IP-10, IL-18 and TGF-b1)
measured at M0 correlated positively with T cell activation at
M6 (Figure 4 B, C and D). Two cytokines (IP-10 and IL-10)
evaluated at M0 were negatively correlated with CD4+ T cell
counts at M6 (Figure 4A and Figure S2). IL-10 levels at M0 were
associated with VL at M6 (Figure S2).
Among all comparisons examined, the best correlations
(rho$0.5) were observed for IP-10, IL-18 and TGF-b1 (at M0)
with T cell activation (at M6).
IP-10 and TGF-b1 were Predictive Factors for RespectivelyCD4+ T Cell Counts and T Cell Activation at Set-point
To analyze whether some of the inflammatory cytokines were
not only associated, but also predictive for one or more of the three
disease progression markers, we performed multivariate linear
regression analyses. After multiple adjustments, none of the 28
proteins in PHI was identified as a predictor for VL at M6. TGFb-
1 and IL-18 at M0 were both positively associated with T cell
activation at M6 (p,0.001 and p = 0.020, respectively). Their
concentration at M0 predicted as much as 74% (adjusted
R2 = 0.74) of the T cell activation values at M6, 66% being
predicted by TGF-b1 alone. IP-10 levels at M0 were negatively
associated with CD4+ T cell counts at M6 (p = 0.021). IP-10
concentration at M0 predicted 30% (adjusted R2 = 0.3) of the
CD4+ T cell count variation at M6.
Plasma IP-10 Levels in Primary Infection Predicted RapidDisease Progression
Next, we studied if the concentrations of one or more of the pro-
and anti-inflammatory proteins, increased in PHI, were predictive
of disease progression. Additionally, we aimed to compare the
Figure 1. Virological and immunological characteristics of the 46 HIV-1 infected patients with three distinct disease progressionprofiles. (A) CD4+ T cell counts (left) and viremia levels (right) are shown over time for the 46 patients, who were divided into 3 groups: slowprogressors (in green, 11 patients), progressors (in blue, 19 patients), rapid progressors (in red, 16 patients). The data were determined in primaryinfection (M0), as well as 1 month (M1) and 6 months (M6) later. The data of the patients are grouped together and the mean and SEM values areshown for each analyzed time point (M0, M1, M6). (B) The CD4+ T cell counts (left) and viremia levels (right) are shown for each single patientaccording to the estimated time post-infection.doi:10.1371/journal.pone.0046143.g001
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Figure 2. Plasma protein levels in HIV-1 infected patients. (A) The levels of 28 proteins in the plasma of 46 acutely infected patients (M0) areexpressed as fold change compared to the levels in healthy donors (N = 17). The order of the proteins is presented according to their function (pro-inflammatory, adaptive, IFN-inducible, chemoattractants, hematopoietic and anti-inflammatory). The anti-inflammatory cytokines are presented onthe right side of the figure. The dotted horizontal line at Y = 1 corresponds to the value in healthy donors. The boxes represent the median and the25th and 75th percentile, with the line in the middle of the boxes corresponding to the median value. Colored boxes stand for the cytokines, whoselevels were significantly different from healthy donors: blue boxes when p,0.05 (as it was the case for IL-1b) and red boxes when p,0.008 (M&Wtest). (B) Protein concentrations at M0, M1 and M6 of the soluble factors that were elevated at M0. The data are expressed in pg/ml, HD: healthydonors, M: months. Cytokine concentrations below the limit of detection were arbitrarily set at the level of the limit of detection. Dot-plots markedwith one asterisk (*) (p,0.05) or two asteriks (**) (p,0.008) represent the cytokines, whose levels were significantly different from healthy donors(M&W test).doi:10.1371/journal.pone.0046143.g002
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capacity of prediction of the soluble proteins with that of CD4+ T
cell counts and VL at M0. Univariate logistic regressions were
performed to analyze if the plasma proteins, CD4+ T cell counts
and VL, categorized according to their respective median values at
M0, were predictive either for slow progression (SP versus P and
RP) or for rapid progression (RP versus P and SP). In the
univariate logistic regression analysis, plasma IP-10 concentration
($869 pg/ml), CD4+ T cell counts (,570 cells/mm3), VL ($5
log10 RNA copies/ml) and plasma IL-10 ($3.7 pg/ml) at M0 were
identified as potentially predictive of rapid disease progression
(Figure 4E). This was not the case neither for IL-18 levels
($673 pg/ml) nor for TGF-b1 levels ($1533 pg/ml). The logistic
regression model revealed that only IP-10 (p = 0.007) and CD4+ T
cell counts (p = 0.020) were independent predictors for rapid
disease progression (Figure 4E).
Validation of the Results Obtained by Luminex on IP-10by ELISA
It was not anticipated that early plasma IP-10 levels could be of
better predictive value than VL and perhaps also slightly better
than CD4+ T cell counts in PHI. In order to confirm these results,
we validated the data obtained with the Luminex technology by
using another, more classical technique for quantification of
proteins, i.e. an Elisa assay. The IP-10 plasma concentration at
M0 was quantified by ELISA in 45 out of the 46 patients (Table 1).
For one patient, no plasma was available for the ELISA. The
prediction values for IP-10 didn’t change using these 45 patients
(not shown). The IP-10 concentration, as determined by ELISA
(median of 249 pg/ml, range: 2–318), strongly correlated with
those measured by Luminex (r = 0.79, p,0.001) (Figure S3).
Univariate regression analyses were then performed. CD4+ T
cell counts ,570 cells/ml (p = 0.007) and in particular IP-
10$249 pg/ml (p = 0.001) were associated with rapid disease
progression, while VL $5 log10 RNA copies/ml only showed a
trend for significance (p = 0.084) (Figure 4E). In the multivariate
regression analysis, IP-10 (p = 0.004) and CD4+ T cells (p = 0.034)
were independently predictive of rapid progression (Figure 4 E).
Thus, the results based on the ELISA were similar to the ones
obtained with the Luminex platform. In both cases, VL in PHI
was not significantly predictive for rapid disease progression, while
CD4+ T cells and to a greater extent IP-10 were.
Validation of Plasma IP-10 Levels in PHI as a PredictiveFactor of Disease Progression
In order to further validate the capacity of early prediction by
IP-10, we replicated the analysis in a blind fashion on an
independent and larger set of patients (N = 88), called the
validation set (Table 1). In contrast to the previous set of patients
(derivation set), the patients of the validation set were not selected
based on distinct profiles of disease progression, but enrolled in a
random manner. They were recruited more recently than patients
of the derivation set and followed for at least 12 months. All were
antiretroviral treatment-naıve.
Plasma IP-10 concentrations during PHI were measured by
ELISA in the 88 HIV-1 infected individuals. The median value of
IP-10 in this validation set (232 pg/ml) was not different from the
one in the derivation set (249 pg/ml) (p = 0.79, Table 1).
We then classified the patients according to their disease
progression profiles, based on their CD4+ T cell counts over time,
as above. As these patients were recruited more recently than the
patients from the derivation set and had been followed for a
shorter period of time, we were only able to define who was a RP,
but could not differentiate between P and SP. However, since the
aim of this analysis was to determine the predictive value of plasma
IP-10 in PHI for rapid disease progression, this did not constitute
an obstacle for our study. The 88 patients split into 17 RP and 71
P/SP. As one could have expected, the proportion of RP in this
validation set was lower (19.3%) than in the previous set (34.8%)
(p = 0.04). For the previous one, we had selected on purpose
similar numbers of individuals in each category of disease
progression. In the second set, individuals were enrolled blindly
without knowing their disease progression profile. The proportion
of RP within the validation set mirrored the normal frequency of
RP in HIV-1 infected individuals [4,28].
There were no significant differences between the derivation
and validation sets in regard to age, gender, estimated time since
infection, CD4+ T cell counts or viremia at M0 (p.0.11) (Table 1).
In the validation set, the CD4+ T cell counts and viremia levels at
M0 were not different when comparing RP to P/SP (P and SP
assembled), in contrast to the derivation set, where CD4+ T cells,
as well as viremia levels, were different between RP and P/SP
already at M0 (Figure 5). This is in line with the random
enrollment of the patients from the validation set. Of note, plasma
IP-10 levels were higher in RP versus P/SP at M0 in the validation
set (p = 0.049), in contrast to CD4+ T cell counts and viremia
(Figure 5 D). The difference in IP-10 levels was though less
pronounced than in the derivation set (p = 0.0002).
Univariate regression analyses were then performed on this
independent set of patients, in order to evaluate the capacity of
plasma IP-10, CD4+ T cell counts and viremia to predict rapid
disease progression. The analysis was again based on the median
IP-10 concentration ($232 pg/ml). Only IP-10 was significant
(p = 0.006), while CD4+ T cell counts and viremia at M0 were not
(Figure 4 E). This was also observed with another categorization of
IP-10, i.e. 3 categories of IP-10 based on the median and third
quartile (not shown). This confirms IP-10 as being a strong
predictive factor of rapid disease progression at this early stage
of infection (PHI).
Overall, the analysis in this independent group of patients
demonstrates that elevated plasma IP-10 level during PHI is of
robust predictive value for rapid evolution towards AIDS. They
confirm the data described above, which already suggested that
during PHI, IP-10 is of stronger prognosis for disease progression
than viremia levels or CD4+ T cell counts.
Discussion
During chronic HIV-1 infection, many plasma proteins and
activation markers, such as neopterin, TNF-a and sCD14, are
associated with progression towards AIDS [9,29]. Here we studied
which plasma proteins during PHI are predictive of the virological
and immunological set-points and of disease progression itself. As
Figure 3. Plasma protein levels at M0 according to disease progression profiles. The cytokine profiles at M0 are shown for each group ofpatients: 16 rapid progressors (A), 19 progressors (B), and 11 slow progressors (C). Color code and statistical analyses are as described in Figure 2(corrected threshold, p,0.005). The dotted horizontal line corresponds to the value in healthy donors. (D) Comparison of protein concentrationsbetween the 3 groups of patients (SP, P and RP). Four representative cytokines are shown. The cytokines increasing significantly over groups were IP-10 and IL-10 (Cuzick’s test, p,0.007). When comparing the groups two by two, out of 28 proteins tested, the levels were different only for IP-10 (M&Wtest,***: p,0.005).doi:10.1371/journal.pone.0046143.g003
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published by others, we detected an increase in many proteins
(such as IP-10, IL-8, IL-10, IL-18, TNF-a, sIL2Ra) during PHI.
These included the same as those previously reported
[6,7,23,24,30]. We did not detect increases of a few other
proteins, reported in some studies [6,7]. For instance, we did not
observe increased levels of two cytokines, IFN-a and IL-15, known
Figure 4. Cytokines predictive of immunological set-point levels. (A–E) Cytokine concentrations in plasma at M0 have been plotted againstCD4+ T cell counts and T cell activation (CD3+CD8+CD38+HLA-DR+) at M6. Six patients, including 4 who were treated at M6, were excluded from theanalysis at M6. T cell activation levels were available for 19 patients at M6 (4 SP, 7 SP, 8 RP). The correlations were thus analyzed in 40 patientsregarding CD4+ T cell counts and viral load and for 19 patients regarding T cell activation. (A) IP-10 levels at M0 plotted against T CD4+ counts at M6.(B) IP-10 levels at M0 plotted against T cell activation at M6. (C) IL-18 levels at M0 plotted against T cell activation at M6. (D) TGF-b1 concentrations atM0 plotted against T cell activation at M6. The red line indicates that both the Spearman correlation and the linear regression analysis weresignificant. (E) Regression analysis for evaluation of the capacity of CD4+ T cell counts, VL and cytokines at M0 to predict rapid disease progression.Values obtained for both the derivation set (Luminex and ELISA) and the validation set are shown. Median values of CD4+ T cell counts, VL andcytokine levels were used: VL . = 5 log; CD4,570 cells (derivation set); CD4,546 cells (validation set); IP-10. = 869 pg/ml (derivation set, Luminex);IP-10. = 247 pg/ml (derivation set, ELISA); IP-10. = 232 pg/ml (validation set, ELISA).doi:10.1371/journal.pone.0046143.g004
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to be produced very early on in PHI. This could be explained by
the fact that the time points analyzed here corresponded mostly to
Fiebig stages III and IV. Of note, we analyzed two soluble factors,
TGF-b1 and sTRAIL, that to our best knowledge have not been
measured before in the plasma during PHI. We observed increases
for both of these proteins, corresponding to data obtained in non-
human primate models [10,11,31,32]. Most importantly, this is the
first time that acute inflammatory protein levels were examined for
their predictive value for T cell activation.
We show here that RP have an increase in both the breadth and
concentration of cytokines induced during PHI as compared to the
other patients groups, and that RP and P, but not SP, presented
early elevation of both pro- (IP-10) and anti-inflammatory (IL-10)
cytokines. It could appear counterintuitive to observe that anti-
inflammatory cytokines were higher in RP and P than in SP
already in PHI, since they should rather dampen the inflamma-
tion. However, it has been reported that IL-10 is induced in a later
stage of PHI, after the first burst of pro-inflammatory cytokines,
both in HIV-1 and SIVmac infections [6,7,9]. The anti-
inflammatory cytokines may thus have been induced as a
consequence of the strong inflammatory response, that is more
pronounced in progressors. Chronic TGF-b1 and IL-10 produc-
tion might then participate in disease progression, for instance by
inhibiting adaptive immune responses [20]. TGF-b1 together with
IL-18 predicted as much as 74% of the T cell activation at set-
point. IL-18 and TGF-b1 have never been studied before for their
predictive value at the early stage of HIV-1 infection. Excessive
TGF-b1 expression in lymph nodes, through the induction of
fibrosis, has been suggested to play a predominant role in the
disruption of lymph node architecture and CD4+ T cell depletion
in HIV and SIV infections [31,33]. IL-18 is known to induce IFN-
c expression, which in turn is capable of inducing IP-10 [34].
IP-10 is shown here to be an independent predictor of rapid
disease progression. This contrasted with the other cytokines, and
even with VL and CD4+ T cell counts, which at this early stage of
infection had, respectively, little or no predictive power. Our study
is not in contradiction with earlier data on VL and CD4+ T cell
counts in PHI as markers of disease progression [4], but suggests
that IP-10 is of stronger predictive value than VL and CD4+ T cell
counts in PHI. The predictive capacities of VL and CD4+ T cell
counts have been analyzed in many studies with large sample sizes
[35]. The role of IP-10 as an early independent predictor of rapid
progression was detected here despite the relatively small number
of patients, supporting its strength. In addition, the data have been
validated in an independent group of patients.
IP-10 has stood out in many other studies. Thus, it has been
previously shown that IP-10 strongly correlates with viremia in
PHI [24], which was also the case here (p = 0.004, not shown). In the
chronic phase of HIV-1 infection, IP-10 showed a strong positive
correlation with VL and a negative one with CD4+ T cell counts
[36,37]. Studies in patients undergoing HAART pinpointed IP-10
to be better correlated with controlled infection than several other
inflammatory markers. In a study where patients started treatment
during PHI, only IP-10 significantly differed between treated and
untreated participants at week 16–24 [7]. Similarly, after Mega-
HAART was initiated during PHI, IP-10 was decreased, whereas
other markers, i.e. sCD14 and LPS, were not [22].
Only two studies however evaluated the capacity of IP-10 to
predict disease progression (over a period of 18 and 24 months),
and contrasting results were reported [24,25]. In the study by
Roberts et al, the first study that ever evaluated the role of acute
inflammation for CD4+ T cell loss, IP-10 was not identified as an
early predictive marker for CD4+ loss [24]. The study was
performed in a cohort of women in South Africa, while in the
ANRS PRIMO cohort, the percentage of patients from sub-
saharan Africa corresponds to only 6.5%, with the vast majority of
patients being Caucasian men (Table 1) [26,27]. Sexually
transmitted infections were frequent among the South-African
women studied, since 94.5% of them were carriers of at least one
infection [24]. Mucosal inflammation can impact on peripheral
markers [23]. Further studies are needed to evaluate whether there
could be a difference with respect to IP-10 as a biomarker between
men and women and in the baseline levels between cohorts in
Europe and Africa [36]. More recently, a study in a cohort of
HIV-1 infected men in China has found IP-10 as an early
predictor of rapid disease progression [25]. This is interesting as it
shows that IP-10 has a similar role as a biomarker in a cohort with
a distinct geographic environment and distinct genetic back-
ground. However, in that study, they did not compare the efficacy
of IP-10 as a biomarker of rapid progression to that of CD4+ T cell
counts and VL. They also did not evaluate the capacity of
cytokines to predict T cell activation.
IP-10 is inducible by IFN-II, but also by other factors, such as
IFN-I [15,38]. In SIVmac-infected macaques, a sustained
production of IFN-I can be observed in lymph nodes
[14,17,39,40]. It is possible that a prolonged production of IFN-
I in lymphoid organs during HIV-1 infection is responsible for the
heightened levels of IP-10. It also not excluded that IP-10
production subsequent to the early peak of IFN-I is fueled by other
factors, such as IFN-c or TNF-a [41]. IP-10 is the ligand of
Table 1. Comparative distribution of patient’s demographic, clinical and immunological characteristics in the derivation andvalidation sets.
Derivation set, N = 45 Validation set, N = 88 p
Gender W/M (% of women) 9/45 (20%) 9/88 (10%) 0.12
Age at enrollment (years) 35 (18–64) 36 (18–67) 0.71
Estimated time post-infection at M0 (days) 51 (28–98) 55 (28–98) 0.83
Blood CD4+ T cells/mm3 (range) 571 (208–1509) 546 (250–1295) 0.94
Plasma viral load (log copies of RNA/ml) 5.03 (2.45–7.21) 4.9 (2.41–7.41) 0.63
IP-10 (pg/ml) 249 (2–1318) 232 (40–2880) 0.79
The main characteristics of the patients are listed here for the time point of enrollment during PHI (M0). For each parameter (except gender), the median values and therange are indicated. Plasma IP-10 concentrations were measured by ELISA at M0. For the derivation set, data are shown for those 45 patients out of 46, whose IP-10 wasquantified by ELISA. The validation set comprised 88 patients. There was no significant difference between the two sets for any parameter (p.0.11). W: women, M: men,N: number of patients in each set.doi:10.1371/journal.pone.0046143.t001
Acute Markers of T Cell Activation and AIDS
PLOS ONE | www.plosone.org 8 October 2012 | Volume 7 | Issue 10 | e46143
Figure 5. Immunological, virological and clinical characteristics of rapid progressors versus progressors and slow progressorsassembled within patients of the derivation and validation sets. The derivation set comprised 46 patients (except for IP-10, where valuesbased on the ELISA were available for only 45 patients). The validation set corresponded to 88 patients for all markers. Differences between rapidprogressors and the other patients are indicated with the presence of a p value (M&W test). P values below 0.05 were considered to be significant.There was no significant difference regarding the time of enrollment at M0 (estimated days post-infection). (A) CD4+ T cells at M0 and M12; (B)Viremia at M0 and M12; (C) number of estimated days post-infection at M0; (D) Plasma IP-10 concentration at M0. M = month.doi:10.1371/journal.pone.0046143.g005
Acute Markers of T Cell Activation and AIDS
PLOS ONE | www.plosone.org 9 October 2012 | Volume 7 | Issue 10 | e46143
CXCR3, which is expressed on many cells (activated T cells, Th1
cells, Treg cells, plasmacytoid dendritic cells, monocytes, NK cells)
and is implicated in the recruitment of CXCR3+ cells to lymph
nodes [42,43,44]. Events in lymph nodes might have a particular
impact on immunodeficiency [45]. IP-10 is known to be produced
in secondary lymphoid organs of viremic HIV-1 infected
individuals and elevated levels in lymph nodes of chronically
infected macaques are associated with more rapid disease
progression [15,18,42,46]. Production of IP-10 in lymph nodes
might amplify the inflammation and the spread of viral infection
by attracting potential target cells of HIV [15,42]. IP-10 enhances
HIV-1 replication in monocyte-derived macrophages and primary
CD4+ T cells in vitro [47]. IP-10 levels have been shown to
correlate with the frequency of pro-inflammatory CD16+ mono-
cytes [37]. It has been suggested that Treg cells, which accumulate
in lymph nodes of progressors, are the major producers of TGF-b1
in lymph nodes [31,48]. Treg cells can express CXCR3 and these
cells could thus be attracted by IP-10. Further studies will be
needed to investigate whether there is a link between IP-10 and
TGF-b1 in lymph nodes and whether IP-10 is only a strong
marker of inflammation and disease progression or whether it also
contributes by itself to immunodeficiency.
Once individuals are diagnosed for HIV infection during PHI,
one of the most pressing decisions confronted by the clinicians is
whether or not to start antiretroviral therapy. Although early
treatment is most likely beneficial for limiting the size of viral
reservoirs, long-term treatment is a burden for the patient. None of
the currently available biomarkers has a perfect sensitivity or
specificity. For instance, VL explains ,50% of the variation in
time from primary infection to the development of clinical AIDS
[49]. Novel early biomarkers, in addition or combination with the
canonical parameters, could help clinicians to refine the decision.
Furthermore, soluble plasma proteins, such as IP-10, would be
ideal biomarkers to assess as they are abundant and easily
measurable.
In conclusion, we show for the first time that the level of
inflammation in primary HIV-1 infection is predictive of T cell
activation levels. This underlines the major role of inflammation in
driving T cell activation, as previously suggested by others [17,50].
Our study highlights the role of TGF-b1 and two IFN-inducible
cytokines (IP10 and IL-18) in determining the immunological set-
points during HIV-1 infection. The plasma concentration of one
single cytokine, IP-10, could even predict on its own rapid disease
progression. Of note, IP-10 level during PHI was better predictive
of rapid progression than viremia or CD4+ T cells counts. IP-10
therefore seems to be a particularly strong early prognosis factor. It
is unknown so far if and which role IP-10 plays in pathogenesis,
but it could be a particular sensitive indicator for the level of
harmful immune activation during HIV-1 infection.
Methods
PatientsThe patients were part of a large, multi-center cohort, named
PRIMO cohort CO06, funded by the French governmental
agency of AIDS research (ANRS) [4,26,27]. The study was
approved by the national Ethics Committee (CCPPRB Paris-
Cochin, Nu1157/18-6-96) and by the Biomedical Research
Committee of Institut Pasteur (2007.020). All patients have given
their written informed consent.
We first performed a retrospective study on 46 patients (Figure 1
and Table S1). These subjects were enrolled between 1999 and
2006, at the stage of PHI. Briefly, in order to be in PHI, the
individuals had to be in the first three months of infection (here
between days 28 and 90 p.i.) with either an incomplete Western
blot, or with a positive p24 antigenemia or detectable HIV RNA
associated with a negative Western blot or a weakly positive
ELISA [4,26,27]. The time since infection, when unknown, has
been estimated as previously described [4,26].
Retroviral treatment-naive patients, showing distinct contrasting
profiles in their spontaneous CD4+ T cell count declines and
viremia levels during a retrospective follow up of 42 months, were
selected for this study (Figure 1 and Table S1). They were divided
into three groups based on their CD4+ T cell profiles: Rapid
progressors (RP) were defined as those loosing their peripheral
CD4+ T cells to below 350 cells/mm3 in less than 12 months (16
patients); Progressors (P) showed more than 350 CD4+ T cells/
mm3 after 12 months but less than 500 cells/mm3 at least at one
time point before or at 42 months post-PHI, in the absence of
treatment (19 patients); and Slow progressors (SP) were displaying
more than 500 CD4+ T cells/mm3 after 42 months post-PHI in
the absence of treatment (11 patients). We analyzed plasma
samples from blood collected on EDTA at time of diagnosis (M0),
as well as 1 month (M1) and 6 months (M6) post-enrollment. None
of the patients were treated at M0, and samples from patients
treated at M1 or M6 (N = 4) were excluded from the analyses.
A second, independent group of 88 patients was enrolled
between 2007 and 2009, at the stage of PHI (Table 1 and Figure 5).
Patients were not treated and followed for at least 12 months.
Blood collected on EDTA was also obtained from 17 healthy
donors through the French blood bank (EFS) as part of the EFS-
Institut Pasteur convention.
Flow CytometryT cell activation was defined as the percentage of activated
CD8+ T cells (CD3+CD8+CD38+HLA-DR+ cells), as described
previously [51]. PBMC from 27 and 19 patients (4 SP, 7 P, 8 RP)
were available for CD8+ T cell activation determination at M0
and M6, respectively.
Cytokine QuantificationTwenty-four plasma proteins were measured using a human
cytokine Milliplex kit (Millipore). For each of the proteins, the limit
of detection was considered as the standard point having a median
fluorescence intensity two fold higher than the blank (see Methods
S1). Plasma levels of transforming-growth-factor b1 (TGF-b1,
Invitrogen), Interleukin 18 (IL-18, Invitrogen) and soluble TNF-
related-apoptosis-inducing-ligand (sTRAIL, R&D) were deter-
mined by ELISA, because they were not available on Luminex
or the detection limits above the physiological concentrations of
the cytokines in the plasma from healthy donors. IP-10 was
measured both by Luminex and ELISA (R&D). Titers of bioactive
IFN-I were determined with a sensitive, functional assay as
previously described [12].
Statistical AnalysesGlobal comparisons were performed using the non-parametric
Kruskal-Wallis test. Two by two group comparisons were based on
the non-parametric Mann and Whitney U-test (M&W) and
adjustments for multiple tests were performed using the ‘‘False
discovery rate’’ (FDR) [52]. Cuzick’s non-parametric test was used
to explore trends across multiple groups. Two-by-two correlations
were evaluated using Spearman correlation coefficient. Cytokines
associated with either VL, CD4+ T cell count and/or T cell
activation set-point levels in univariate linear regression analyses
(p,0.10) were included in the final multivariate models in a
stepwise manner to identify independent predictors. For each
analysis, the same and thus equal number of patients were used.
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PLOS ONE | www.plosone.org 10 October 2012 | Volume 7 | Issue 10 | e46143
To satisfy the normality assumption, CD4+ T cell counts and T
cell activation levels were modeled after log10 transformation.
Logistic regression analyses were used to estimate the prediction
capacity of early cytokine concentrations for CD4+ T cell counts
and T cell activation levels at set-point, as well as to study the
predictivity of cytokine levels for slow progression (SP versus P and
RP) or rapid progression (RP versus P and SP). All factors
associated in univariate analyses (p,0.10) were included in the
multivariate logistic regressions. VL was incorporated into the
multivariate models to estimate the prediction for CD4+ T cell
counts and T cell activation. CD4+ T cell numbers were
additionally incorporated in the analyses for the prediction of T
cell activation levels.
Supporting Information
Figure S1 Plasma protein levels at M1 and M6 accord-ing to disease progression profiles. The plasma protein
levels at M1 (A) and M6 (B) were expressed as fold change
compared to those in healthy donors. Significant changes are
indicated as red boxes (corrected threshold p,0.002). When a
cytokine was increased (p,0.05), but the p-value was not under
the corrected threshold (p,0.002) it was represented in a yellow
box (p,0.005 on A and p,0.008 on B). The cytokines are listed
from left to right according to their role (inflammatory, adaptive,
IFN-inducible, chemoattractive, hematopoietic and anti-inflam-
matory). The dotted horizontal line corresponds to the respective
values in healthy donors.
(DOC)
Figure S2 Correlation between plasma cytokine levelsat M0 and disease progression markers. The cytokine
concentrations at M0 have been plotted against (A) T CD4+ counts
(N = 40), (B) viremia (N = 40) and (C) T cell activation
(CD3+CD8+CD38+HLADR+, N = 19) levels at set point (M6).
Here are represented the 5 cytokines (IP-10, IL-18, MCP-1, IL-10,
TGF-b1) correlated with one (or more) of the disease progression
markers (Spearman correlation). A red line indicates both a
significant correlation and a significant linear regression. A black
dotted line represents a non-significant linear regression. VL: viral
load.
(DOC)
Figure S3 Correlation between IP-10 plasma concentra-tions quantified by Luminex and by Elisa. The IP-10
concentrations were determined in 45 patients during primary
HIV-1 infection.
(DOC)
Table S1 Demographic, clinical, virological and immu-nological characteristics of the 46 HIV-1 infectedpatients belonging to the derivation set. For each
parameter, the median value is indicated. There were no
significant differences between the groups concerning age
(p = 0.65), gender (p = 0.32) or estimated time since infection
(p = 0.4) (M&W test). In contrast, the three groups of patients
presented differences in their T CD4+ counts and VL levels (see
also Table S2). RP: Rapid progressors, P: progressors, SP: Slow
progressors. The symbol 1 indicates a significant difference
between SP and RP, * a difference between P and SP and #
between RP and P (p,0.05). W: women, M: men, N: number of
patients in each group.
(DOC)
Table S2 Comparison of viral load and T CD4+ countsbetween RP, P and SP of the derivation set. The VL and
CD4+ T cell counts have been compared between the groups of
patients described in Figure 1 and Table S1. The p-values are
shown here for each comparison (M&W U-test). In red are
indicated the statistically significant differences (p,0.05).
M = month, RP = rapid progressor, P = progressor, SP = slow
progressor.
(DOC)
Table S3 Plasma protein profiles according to diseaseprogression. The plasma proteins significantly elevated in one
or more groups (RP for rapid progressors, P for progressors and SP
for slow progressors) are shown here for the three time points: M0
(primary infection), M1 and M6. ‘‘+’’ stands for a significant
difference as compared to healthy donors (M&W test, FDR
corrected threshold: p,0.005 at M0, p,0.002 at M1 and M6). A
‘‘-‘‘ stands for no change. M = month.
(DOC)
Methods S1 Luminex assay. Twenty-four plasma proteins
were measured using a human cytokine Milliplex kit (Millipore):
Fibroblast-growth-factor 2 (FGF-2), FMS-like-tyrosine-kinase-3-
Ligand (FLT-3L), Fractalkine, Granulocyte-colony-stimulating
factor (G-CSF), Granulocyte-macrophage-colony-stimulating fac-
tor (GM-CSF), Interferon c (IFN-c), Interleukin 1 b (IL-1b), IL-2,
IL-6, IL-7, IL-8, IL-9, IL-10, IL-12p70, IL-15, IL-17, IP-10,
macrophage-derived-chemokine (MDC), macrophage-inflamma-
tory-protein 1a and b (MIP-1a, MIP-1b), monocyte-chemotactic-
protein 3 (MCP-3), regulated-upon-activation-normal-T-cell-ex-
pressed and secreted (Rantes), soluble-IL2 receptor a (sIL2Ra) and
tumor-necrosis-factor a (TNF-a). The limit of detection was
3.2 pg/ml except for: FLT-3L, G-CSF, GM-CSF, IL-7 and MIP-
1b (16 pg/ml); FGF-2, MCP-3 and MIP-1a (40 pg/ml); and IP-
10, Fractalkine and sIL2Ra (80 pg/ml). The standards (3.2 to
10,000 pg/ml) of the manufacturer were run on each plate in
duplicate. All samples were assayed concurrently to avoid inter-
assay variability. Data were acquired using a Luminex-100 system
and analyzed using Bio-Plex Manager Software (Applied-Cytom-
etry).
(DOC)
Acknowledgments
The authors are grateful to the patients and clinicians from the
participating centers of the French PRIMO cohort (ANRS CO06) for
their participation and efficient collaboration. We thank Y. Madec for
helpful discussions. We are thankful to M.J. Ploquin, A. Saez-Cirion and
M.C. Saleh for critical reading of the manuscript and to M.E. Laird for
precious support in editing. We would like to acknowledge the ‘‘Centre
d’Immunologie Humaine’’ (CIH) of the Institut Pasteur for access to the
Luminex machine.
Author Contributions
Coordinated patient samples from the Cohort: LM YZ AV MS. Conceived
and designed the study: MS MMT. Performed the experiments: ASL CL
BJ IG GP PL. Designed and performed the statistical analyses: MARC
LM. Analyzed the data: ASL MS AV FBS LM MARC MMT. Wrote the
manuscript: ASL MARC MMT.
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PLOS ONE | www.plosone.org 11 October 2012 | Volume 7 | Issue 10 | e46143
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